Environmental assessment of building properties — Where natural and social sciences meet: the case of EcoEffect

Assefa, Getachew

KTH, School of Chemical Science and Engineering (CHE), Chemical Engineering and Technology.

Glaumann, Mauritz

Department of Technology and Built Environment, University of Gävle.

Malmqvist, Tove

KTH, School of Architecture and the Built Environment (ABE), Architecture. KTH, School of Architecture and the Built Environment (ABE), Urban Planning and Environment, Environmental Strategies (moved 20130630).ORCID iD: 0000-0003-2949-422X

Abstract [en]

The EcoEffect method of assessing external and internal impacts of building properties is briefly described. The external impacts of manufacturing and transport of the building materials, the generation of power and heat consumed during the operation phase are assessed using life-cycle methodology. Emissions and waste; natural resource depletion and toxic substances in building materials are accounted for. Here methodologies from natural sciences are employed. The internal impacts involve the assessment of the risk for discomfort and ill-being due to features and properties of both the indoor environment and outdoor environment within the boundary of the building properties. This risk is calculated based on data and information from questionnaires; measurements and inspection where methodologies mainly from social sciences are used. Life-cycle costs covering investment and utilities costs as well as maintenance costs summed up over the lifetime of the building are also calculated.

The result presentation offers extensive layers of diagrams and data tables ranging from an aggregated diagram of environmental efficiency to quantitative indicators of different aspects and factors. Environmental efficiency provides a relative measure of the internal quality of a building property in relation to its external impact vis-à-vis its performance relative to other building properties.

Assefa, Getachew

KTH, School of Chemical Science and Engineering (CHE), Chemical Engineering and Technology.

2005 (English)Doctoral thesis, comprehensive summary (Other academic)

Abstract [en]

Engineering research and development work is undergoing a reorientation from focusing on specific parts of different systems to a broader perspective of systems level, albeit at a slower pace. This reorientation should be further developed and enhanced with the aim of organizing and structuring our technical systems in meeting sustainability requirements in face of global ecological threats that have far-reaching social and economic implications, which can no longer be captured using conventional approach of research. Until a list of universally acceptable, clear, and measurable indicators of sustainable development is developed, the work with sustainability metrics should continue to evolve as a relative measure of ecological, economic, and social performance of human activities in general, and technical systems in particular. This work can be done by comparing the relative performance of alternative technologies of providing the same well-defined function or service; or by characterizing technologies that enjoy different levels of societal priorities using relevant performance indicators. In both cases, concepts and methods of industrial ecology play a vital role.

This thesis is about the development and application of a systematic approach for the assessment of the performance of technical systems from the perspective of systems analysis, sustainability, sustainability assessment, and industrial ecology.

The systematic approach developed and characterized in this thesis advocates for a simultaneous assessment of the ecological, economic, and social dimensions of performance of technologies in avoiding sub-optimization and problem shifting between dimensions. It gives a holistic picture by taking a life cycle perspective of all important aspects. The systematic assessment of technical systems provides an even-handed assessment resulting in a cumulative knowledge. A modular structure of the approach makes it flexible enough in terms of comparing a number of alternatives at the same time, and carrying out the assessment of the three dimensions independently. It should give way to transparent system where the level of quality of input data can be comprehended. The assessment approach should focus on a selected number of key input data, tested calculation procedures, and comprehensible result presentation.

The challenge in developing and applying this approach is the complexity of method integration and information processing. The different parts to be included in the same platform come in with additional uncertainties hampering result interpretations. The hitherto tendency of promoting disciplinary lines will continue to challenge further developments of such interdisciplinary approaches.

The thesis draws on the experience from ORWARE, a Swedish technology assessment tool applied in the assessment of waste management systems and energy systems; and from the EcoEffect tool used in the assessment of building properties; all assessed as components of a larger system. The thesis underlines the importance of sustainability considerations beginning from the research and development phase of technical systems. The core message of this thesis is that technical systems should be researched as indivisible parts of a complex whole that includes society and the natural environment. Results from such researches can then be transformed into design codes and specifications for use in the research and development, planning and structuring, and implementation and management of technical systems.